garnet/app/Main.hs

module Main (main) where

import Control.Monad
import Control.Monad.State
import Data.Bifunctor
import Data.ByteString.Lazy qualified as BL
import Data.Functor
import Data.Maybe
import Data.Text (Text)
import Data.Text qualified as T
import Data.Text.Encoding (encodeUtf8)
import Data.Text.IO qualified as T
import Data.Void
import Test.Tasty
import Test.Tasty.Golden (goldenVsString)
import Test.Tasty.Ingredients.ConsoleReporter
import Text.Megaparsec hiding (Pos)
import Text.Megaparsec.Char
import Text.Megaparsec.Char.Lexer qualified as Lex

main :: IO ()
main =
    defaultMain
        . localOption (Always :: UseColor)
        $ testGroup
            "tests"
            [ puzzleTest puzzle1
            , puzzleTest puzzle2
            ]

puzzleTest :: Puzzle -> TestTree
puzzleTest Puzzle{number, parser, parts} =
    testGroup pt $
        ["examples", "real"] <&> \t ->
            withResource (parseFile $ "inputs/" <> t <> "/" <> pt) mempty \input ->
                testGroup t $
                    zip (map show [1 :: Int ..]) parts <&> \(n, pp) ->
                        goldenVsString n ("outputs/" <> t <> "/" <> pt <> "/" <> n) $
                            BL.fromStrict . encodeUtf8 . pp <$> input
  where
    pt = show number
    parseFile fp =
        either (fail . ("parse failure: " <>) . errorBundlePretty) pure . runParser (parser <* eof) fp
            =<< T.readFile fp

data Puzzle = forall input. Puzzle
    { number :: Word
    , parser :: Parsec Void Text input
    , parts :: [input -> Text]
    }

puzzle1 :: Puzzle
puzzle1 =
    Puzzle
        { number = 1
        , parser = flip sepEndBy newline $ (,) <$> ((char 'L' $> L) <|> (char 'R' $> R)) <*> (Inc <$> Lex.decimal)
        , parts =
            [ T.show
                . sum
                . flip evalState 50
                . traverse \(d, i) -> state \p ->
                    let (_, p') = step i d p
                     in (Count if p' == 0 then 1 else 0, p')
            , T.show
                . sum
                . flip evalState 50
                . traverse \(d, i) -> state \p ->
                    let (c, p') = step i d p
                        c' = case d of
                            R -> abs c
                            L ->
                                if
                                    | p == 0 -> abs c - 1
                                    | p' == 0 -> abs c + 1
                                    | otherwise -> abs c
                     in (c', p')
            ]
        }

data Direction = L | R
    deriving (Eq, Ord, Show)

newtype Pos = Pos Int
    deriving newtype (Eq, Ord, Show, Num)

newtype Inc = Inc Int
    deriving newtype (Eq, Ord, Show, Num)

newtype Count = Count Int
    deriving newtype (Eq, Ord, Show, Num)

step :: Inc -> Direction -> Pos -> (Count, Pos)
step (Inc i) d (Pos p) = bimap Count Pos case d of
    L -> (p - i) `divMod` 100
    R -> (p + i) `divMod` 100

puzzle2 :: Puzzle
puzzle2 =
    Puzzle
        { number = 2
        , parser = (<* newline) $ flip sepBy (char ',') $ (,) <$> (Lex.decimal <* char '-') <*> Lex.decimal
        , parts =
            [ T.show
                . sum
                . concatMap
                    (mapMaybe (\n -> guard (isRepetition n) $> n) . uncurry enumFromTo)
            ]
        }

newtype ID = ID Int
    deriving newtype (Eq, Ord, Show, Num, Enum)

isRepetition :: ID -> Bool
isRepetition (T.show -> n) = uncurry (==) $ T.splitAt (T.length n `div` 2) n
Solve day 1 2025-12-02 01:37:59 +00:00			`module Main (main) where`

Solve day 2 part 1 2025-12-02 10:54:12 +00:00			`import Control.Monad`
Solve day 1 2025-12-02 01:37:59 +00:00			`import Control.Monad.State`
Solve day 1 part 2 2025-12-02 01:44:53 +00:00			`import Data.Bifunctor`
Use Tasty 2025-12-02 08:23:53 +00:00			`import Data.ByteString.Lazy qualified as BL`
			`import Data.Functor`
Solve day 2 part 1 2025-12-02 10:54:12 +00:00			`import Data.Maybe`
Use Tasty 2025-12-02 08:23:53 +00:00			`import Data.Text (Text)`
			`import Data.Text qualified as T`
			`import Data.Text.Encoding (encodeUtf8)`
Use `Text` 2025-12-02 09:11:42 +00:00			`import Data.Text.IO qualified as T`
Refactor to use Megaparsec 2025-12-02 09:08:43 +00:00			`import Data.Void`
Use Tasty 2025-12-02 08:23:53 +00:00			`import Test.Tasty`
			`import Test.Tasty.Golden (goldenVsString)`
Force Tasty to use colours in GHCID 2025-12-02 09:30:39 +00:00			`import Test.Tasty.Ingredients.ConsoleReporter`
Refactor to use Megaparsec 2025-12-02 09:08:43 +00:00			`import Text.Megaparsec hiding (Pos)`
			`import Text.Megaparsec.Char`
			`import Text.Megaparsec.Char.Lexer qualified as Lex`
Initial 2025-12-02 00:32:49 +00:00
			`main :: IO ()`
Use Tasty 2025-12-02 08:23:53 +00:00			`main =`
Reformat 2025-12-02 09:38:31 +00:00			`defaultMain`
			`. localOption (Always :: UseColor)`
			`$ testGroup`
Use Tasty 2025-12-02 08:23:53 +00:00			`"tests"`
			`[ puzzleTest puzzle1`
Solve day 2 part 1 2025-12-02 10:54:12 +00:00			`, puzzleTest puzzle2`
Use Tasty 2025-12-02 08:23:53 +00:00			`]`
Refactor to make things more reusable 2025-12-02 02:01:37 +00:00
Refactor to use existential 2025-12-02 11:21:04 +00:00			`puzzleTest :: Puzzle -> TestTree`
Refactor to use field puns 2025-12-02 11:20:48 +00:00			`puzzleTest Puzzle{number, parser, parts} =`
Minor refactor 2025-12-02 08:53:18 +00:00			`testGroup pt $`
Move submodule and symlink to make paths simpler 2025-12-02 08:51:14 +00:00			`["examples", "real"] <&> \t ->`
Minor refactor 2025-12-02 08:55:32 +00:00			`withResource (parseFile $ "inputs/" <> t <> "/" <> pt) mempty \input ->`
Format 2025-12-02 08:51:26 +00:00			`testGroup t $`
Refactor to use wildcard 2025-12-02 11:20:00 +00:00			`zip (map show [1 :: Int ..]) parts <&> \(n, pp) ->`
Minor refactor 2025-12-02 08:53:18 +00:00			`goldenVsString n ("outputs/" <> t <> "/" <> pt <> "/" <> n) $`
Simplify part solver types This also gives us the flexibility to have all tests passing when only part 1 is complete. 2025-12-02 11:14:54 +00:00			`BL.fromStrict . encodeUtf8 . pp <$> input`
Minor refactor 2025-12-02 08:53:18 +00:00			`where`
Refactor to use wildcard 2025-12-02 11:20:00 +00:00			`pt = show number`
Reformat 2025-12-02 10:46:06 +00:00			`parseFile fp =`
Refactor to use wildcard 2025-12-02 11:20:00 +00:00			`either (fail . ("parse failure: " <>) . errorBundlePretty) pure . runParser (parser <* eof) fp`
Reformat 2025-12-02 10:46:06 +00:00			`=<< T.readFile fp`
Compare example results against expectations 2025-12-02 08:07:33 +00:00
Refactor to use existential 2025-12-02 11:21:04 +00:00			`data Puzzle = forall input. Puzzle`
Refactor to make things more reusable 2025-12-02 02:01:37 +00:00			`{ number :: Word`
Use `Text` 2025-12-02 09:11:42 +00:00			`, parser :: Parsec Void Text input`
Simplify part solver types This also gives us the flexibility to have all tests passing when only part 1 is complete. 2025-12-02 11:14:54 +00:00			`, parts :: [input -> Text]`
Refactor to make things more reusable 2025-12-02 02:01:37 +00:00			`}`

Refactor to use existential 2025-12-02 11:21:04 +00:00			`puzzle1 :: Puzzle`
Refactor to make things more reusable 2025-12-02 02:01:37 +00:00			`puzzle1 =`
			`Puzzle`
			`{ number = 1`
Refactor to use Megaparsec 2025-12-02 09:08:43 +00:00			`, parser = flip sepEndBy newline $ (,) <$> ((char 'L' $> L) <\|> (char 'R' $> R)) <*> (Inc <$> Lex.decimal)`
Simplify part solver types This also gives us the flexibility to have all tests passing when only part 1 is complete. 2025-12-02 11:14:54 +00:00			`, parts =`
Format 2025-12-02 11:15:49 +00:00			`[ T.show`
			`. sum`
			`. flip evalState 50`
			`. traverse \(d, i) -> state \p ->`
			`let (_, p') = step i d p`
			`in (Count if p' == 0 then 1 else 0, p')`
			`, T.show`
			`. sum`
			`. flip evalState 50`
			`. traverse \(d, i) -> state \p ->`
			`let (c, p') = step i d p`
			`c' = case d of`
			`R -> abs c`
			`L ->`
			`if`
			`\| p == 0 -> abs c - 1`
			`\| p' == 0 -> abs c + 1`
			`\| otherwise -> abs c`
			`in (c', p')`
Simplify part solver types This also gives us the flexibility to have all tests passing when only part 1 is complete. 2025-12-02 11:14:54 +00:00			`]`
Refactor to make things more reusable 2025-12-02 02:01:37 +00:00			`}`
Solve day 1 2025-12-02 01:37:59 +00:00
			`data Direction = L \| R`
			`deriving (Eq, Ord, Show)`

			`newtype Pos = Pos Int`
			`deriving newtype (Eq, Ord, Show, Num)`

			`newtype Inc = Inc Int`
			`deriving newtype (Eq, Ord, Show, Num)`

			`newtype Count = Count Int`
			`deriving newtype (Eq, Ord, Show, Num)`

Solve day 1 part 2 2025-12-02 01:44:53 +00:00			`step :: Inc -> Direction -> Pos -> (Count, Pos)`
			`step (Inc i) d (Pos p) = bimap Count Pos case d of`
			L -> (p - i) `divMod` 100
			R -> (p + i) `divMod` 100
Solve day 2 part 1 2025-12-02 10:54:12 +00:00
Refactor to use existential 2025-12-02 11:21:04 +00:00			`puzzle2 :: Puzzle`
Solve day 2 part 1 2025-12-02 10:54:12 +00:00			`puzzle2 =`
			`Puzzle`
			`{ number = 2`
			`, parser = (<* newline) $ flip sepBy (char ',') $ (,) <$> (Lex.decimal <* char '-') <*> Lex.decimal`
Simplify part solver types This also gives us the flexibility to have all tests passing when only part 1 is complete. 2025-12-02 11:14:54 +00:00			`, parts =`
Format 2025-12-02 11:15:49 +00:00			`[ T.show`
			`. sum`
			`. concatMap`
			`(mapMaybe (\n -> guard (isRepetition n) $> n) . uncurry enumFromTo)`
Simplify part solver types This also gives us the flexibility to have all tests passing when only part 1 is complete. 2025-12-02 11:14:54 +00:00			`]`
Solve day 2 part 1 2025-12-02 10:54:12 +00:00			`}`

			`newtype ID = ID Int`
			`deriving newtype (Eq, Ord, Show, Num, Enum)`

			`isRepetition :: ID -> Bool`
			isRepetition (T.show -> n) = uncurry (==) $ T.splitAt (T.length n `div` 2) n